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Topic: Linear Actuator construction (Read 4414 times)

I am looking to construct a linear actuator. My basic requirement is to use 2 linear actuators to raise and lower the panel along one single axis. So if any can guide me to the right resources where i can design the required components for the linear actuator. I am medium lvl user of CATIA.

Just to add...If the panel are hinged in one side, it should be easy to do - just use a counterweight. Properly balanced, you can make do with very little power, whether it's coming from rope and pulleys, a linear actuator or whatever.

Linear actuators are quite expensive, compared with other means, so if a regular (geared down) motor could be mounted on aforementioned counterweight, you'll save money and trouble.

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Regards,Søren

A rather fast and fairly heavy robot with quite large wheels needs what? A lot of power?Please remember...Engineering is based on numbers - not adjectives

Thanks for the suggestions. I am very new to this . I am from India and from a city where i don't have much options to choose from.

I am trying to make a solar tracker which should be inclined at 14˚ and still be able to rotate it on a single axis (around 140˚ of total rotation of panel). what kind of hinge or joint or support I can use for panel rotation. I have very less knowledge about the mechanical stuff. So Any suggestions will help me a lot.

If I just use 1 linear actuator...how can i decide the thread thickness and pitch for the linear actuator shaft. what should be used to hold it different angles. As mentioned before the panel weight is 12-13kg.

I will be grateful to any kind of help that can guide me to my objective.

For the hinge I'd just drill some nylon bushings. Or even steel on steel might be fine with a bit of grease. Or steel shaft in wooden holes. Anything really!

You should really use a counterweight. Then the weight of the panel won't matter for the actuator. Friction in the bearing, friction in the threaded rod and error in the counterweight are probably the biggest factors influencing the force requirements. Calculate using tangential force = torque / radius. Do the force calculation for extreme points in the travel because it might get pretty tight with that wide range of motion.

You also need to make sure it doesn't break in the wind. You can do some really rough drag coefficient calcs (see Wikipedia) to estimate the force based on the maximum expected wind speed.

Or you can just get any old threaded rod you find. I don't know if you can be bothered calculating things, intuition can be enough.

I am trying to make a solar tracker which should be inclined at 14˚ and still be able to rotate it on a single axis (around 140˚ of total rotation of panel). what kind of hinge or joint or support I can use for panel rotation. I have very less knowledge about the mechanical stuff. So Any suggestions will help me a lot.

If I understand you right, that the solar panel is to be rotated with a steady inclination, you don't need a linear actuator.

This can be made from whatever you have (Water resistant plywood would be great):Better resolutionA large cogwheel and a heavily geared down motor (DC or whatever) can be used, as you want 0.0007 RPM (1 revolution in 24 hours) to follow the sun.You will need some circuitry to control it of course and you will want to close the open side of the panel support to make it wind resistant.The board shown should run on a similar board where the center axle keeps it in place.

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Regards,Søren

A rather fast and fairly heavy robot with quite large wheels needs what? A lot of power?Please remember...Engineering is based on numbers - not adjectives

It seems all the Barn Doors are of the gull wing type (like on a Lamborghini ), as they're only controlled vertically.The solar tracker is controlled horizontally instead (and will only work well in a "narrow" belt around equator, due to the fixed vertical - or it should have both axis controllable to maximize output).

If you have seen photos of stars from a steady mounted cam, they are circle segments (at least when closer to the poles) and it seems that the Barn Door contraptions are only good for 10 min. max. for that reason.A better approach would be to control both axis (entering the position of the object in question) as it would allow much longer exposures. It would take a really steady foundation though.

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Regards,Søren

A rather fast and fairly heavy robot with quite large wheels needs what? A lot of power?Please remember...Engineering is based on numbers - not adjectives

Correct on all counts Søren. There are other factors to consider in astrophotography but are beyond the scope of this tread.

The one relevant point is that the astrophotography barn door trackers have the hinge aligned parallel to the Earth's axis therefore only a single motion is required to track the Stars (actually countering the Earth's rotation). This is also know as a Polar aligned mount.

I am not planning to make dual axis tracker for this experiment.. The reason I was asking for some design that involves linear actuator is, I got a friend who can make a linear actuator if i can guide him well enough with exact process & specifications. And right now I only want to try single axis tracker. I already have another panel fixed at 14˚ inclination which is good for my place around the year.

I now want to make another panel at same inclination and track the sun from morning to evening from east to west. This is what I want to do so I can compare the efficiency increase between fixed and single axis tracker.

I have to use linear actuator as it is part of the project My prof wants. I know we can use other options, but any help that i can get in making this possible will be appreciated.